Laser-based cleaning device for film analysis tool

ABSTRACT

A system for analyzing a thin film uses an energy beam, such as a laser beam, to remove a portion of a contaminant layer formed on the thin film surface. This cleaning operation removes only enough of the contaminant layer to allow analysis of the underlying thin film, thereby enhancing analysis throughput while minimizing the chances of recontamination and/or damage to the thin film. An energy beam source can be readily incorporated into a conventional thin film analysis tool, thereby minimizing total analysis system footprint. Throughput can be maximized by focusing the probe beam (or probe structure) for the analysis operation at the same location as the energy beam so that repositioning is not required after the cleaning operation. Alternatively, the probe beam (structure) and the energy beam can be directed at different locations to reduce the chances of contamination of the analysis optics.

RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No. 10/056,271, entitled “Laser-Based Cleaning Device for Film Analysis Tool” filed Jan. 23, 2002.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to field of thin film measurement, and in particular to a method and apparatus for cleaning the surface of a thin film to improve measurement accuracy.

2. Background of the Invention

As the dimensions of semiconductor devices continue to shrink, accurate and efficient characterization of the components forming those devices becomes more critical. Typically, the manufacturing process for modern semiconductor devices includes the formation of a number of layers or “thin films” on a silicon wafer. The thin films can include oxide, nitride, and/or metal layers, among others. To ensure proper performance of the finished semiconductor devices, the thickness and composition of each thin film formed during the manufacturing process must be tightly controlled.

Modern thin films have reached the point where the accuracy and reproducibility of thin film measurements can be limited by contamination on the surface of the thin film. For example, the absorption of water and other vapors onto the thin film can create a contaminant layer that adversely affects thin film analysis technique such as optical ellipsometry optical reflectometry, grazing-incidence x-ray reflectometry (GXR), x-ray fluorescence (XRF), electron microprobe analysis (EMP), and non-contact electrical analysis—all of which operate by directing a probe beam (optical, x-ray, electron or corona discharge) at the surface of the thin film to be measured. The contaminant layer can also interfere with measurements techniques that physically contact the surface of the thin film, such as contact-based electrical analysis (e.g., spreading resistance analysis).

Conventional methods for cleaning thin films heat the entire wafer in an oven to a temperature of about 300° C. to vaporize any contaminant layer. FIG. 1 a shows a conventional oven-based wafer cleaning system 100 a used to prepare a wafer 110 for thin film analysis, as described in U.S. Pat. No. 6,325,078, issued Dec. 4, 2001 to Kamieniecki. Wafer 110 includes a thin film layer 112 formed on a silicon substrate 111, and a contaminant layer 113 formed on the surface of thin film layer 112. Wafer cleaning system 10 a comprises a wafer stage 120 and multiple heat lamps 130. Wafer stage 120 positions wafer 110 under heat lamps 130, where thermal radiation from heat lamps 130 heats wafer 110 to vaporize contaminant layer 113. It is believed that this cleaning process is aided by the optical photons from heat lamps 130 effectively breaking bonds between contaminant layer 113 and thin film layer 112.

FIG. 1 b shows another conventional wafer cleaning system 100 b used to prepare wafer 110 for thin film analysis, as described in U.S. Pat. No. 6,261,853, issued Jul. 17, 2001 to Howell et al. Just as described with respect to FIG. 1 a, wafer 110 includes a thin film layer 112 formed on a silicon substrate 111 and a contaminant layer 113 formed on the surface of thin film layer 112. Cleaning system 100 b incorporates a stage 140 that includes a heating element 141. Heat generated by heating element 141 is conducted through stage 140 into wafer 110, thereby providing the heating required to vaporize contaminant layer 113. A heat exchanger 150 coupled to stage 140 captures excess heat from heating element 141, thereby minimizing undesirable heating of cleaning system 100 b itself and the surrounding environment.

Although wafer cleaning systems 100 a and 100 b use different thermal energy sources (i.e., heat lamps 130 and heating element 141, respectively), both systems perform a bulk heating operation to remove contaminant layer 113. The large thermal control components (e.g., lamps, heated stages, heat exchangers, etc.) typically used for bulk wafer heating undesirably increase the cleanroom space required for these conventional cleaning systems. Further exacerbating the problem of excess equipment size, conventional cleaning systems are sometimes stand-alone units used in conjunction with a thin film analysis tool. Therefore, conventional cleaning systems can significantly increase the total footprint required for a complete thin film analysis system. The use of a separate cleaning system also has an adverse effect on throughput, as time must be spent transferring the wafer to and from the cleaning system. In addition, contaminants can redeposit on the cleaned wafer when it is transferred from the cleaning system to the film analysis tool.

In an attempt to somewhat alleviate these equipment size and recontamination problems, attempts have been made to combine wafer cleaning and measurement capabilities in a single tool. For example, the aforementioned U.S. Pat. No. 6,261,853 describes integrating cleaning system 100 b with an existing metrology tool (Opti-Probe 5240 from Therma-Wave, Inc.). Also, the Quantox XP tool from KLA-Tencor integrates a wafer cleaning system similar to cleaning system 100 b with a non-contact electrical film measurement system. However, any bulk wafer heating system must still incorporate the aforementioned (large) thermal control components. Furthermore, even if a combined system is used, the bulk heating operation can significantly degrade overall wafer processing throughput. Several seconds are required to heat the wafer to the temperature required for removal of the contaminant layer, and another several seconds are required to cool down the wafer after cleaning. Any wafer handling operations that must be performed during and after the cleaning operation (e.g., transferring the wafer from the cleaning system to the thin film analysis system) further reduce the throughput.

Accordingly, it is desirable to provide an efficient wafer cleaning system for thin film measurement systems that does not require lengthy heating and cooling times and does not require dedicated wafer handling steps.

SUMMARY

The present invention provides localized contaminant layer removal from a thin film surface, thereby enabling accurate and repeatable analysis of the thin film by a measurement tool. By using a concentrated energy beam to clean only the portion of the thin film to be measured by the measurement tool, the thin film analysis can be performed without the long heating and cooling times associated with conventional cleaning systems. Furthermore, the compact components used in an energy beam-based cleaning system can be incorporated into the thin film measurement tool itself, thereby eliminating any delays related to transferring the wafer to and from a stand-alone cleaning system. This integration also minimizes the total footprint required for a thin film analysis system, and since the wafer can be cleaned and analyzed in the same process chamber, redeposition of contaminants on the cleaned portion of the wafer can be prevented.

A thin film analysis system in accordance with an embodiment of the present invention comprises an energy beam source, an analysis module, and a stage. The stage holds a test sample (such as a wafer) that includes a thin film layer to be measured by the analysis module. The analysis module can comprise any thin film analysis system or systems, including a single-wavelength ellipsometer (SWE, such as described in co-owned, co-pending U.S. patent application Ser. No. 09/298,007), a spectroscopic ellipsometer (SE, such as described in co-owned U.S. Pat. No. 5,608,526), a reflectometer (such as described in co-owned U.S. Pat. No. 5,747,813), a non-contact electrical measurement system (such as described in co-owned U.S. Pat. No. 5,485,091), a GXR system (such as described in co-owned, co-pending U.S. patent application Ser. No. 10/005,610), a contact-based electrical measurement system, an XRF system, and/or an EMP system. More generally, this cleaning system can be used with any sort of inspection or metrology system used in the production of semiconductor devices. According to an embodiment of the present invention, the energy beam source is incorporated into a conventional thin film analysis tool, thereby minimizing the total footprint of the thin film analysis system.

The energy beam source is configured to direct an energy beam at a contaminant layer on the surface of the thin film layer. The energy beam heats a portion of the contaminant layer until that portion of the contaminant layer is vaporized. This process can be aided by direct photon excitation of the bonds between the contaminant layer and the thin film layer. The area of the thin film layer exposed by this cleaning operation can then be analyzed by the analysis module. The size of this analysis area required by the analysis module for performance of the thin film analysis can be used to determine the minimum required power and size of the energy beam. By minimizing the power and size of the energy beam, the risk of damage to the test sample is small. This risk of damage can be further reduced by performing the cleaning and measuring operations at non-functional regions of the test sample. According to an embodiment of the present invention, the energy beam source can comprise a laser, such as a Q-switched pulsed laser. According to another embodiment of the present invention, the energy beam source can comprise a flashlamp with appropriate focusing optics.

According to an embodiment of the present invention, a probe beam generated by the analysis module (e.g., a low-power laser beam, a white light beam, a corona discharge, an x-ray beam, etc.) is directed at the same location on the test sample as the energy beam produced by the energy beam source. Alternatively, a physical probe structure (e.g., a four-point probe in a spreading resistance tool) (can be aimed at the same location on the test sample as the energy beam produced by the energy beam source. Consequently, the test sample does not need to be moved between the cleaning and measurement operations, thereby maximizing analysis throughput. Furthermore, because the measurement operation can be performed immediately after the cleaning operation, the chances of the cleaned portion of the thin film layer (i.e., the analysis area) being recontaminated before the measurement operation are minimized.

According to another embodiment of the present invention, the probe beam (or probe structure) from the analysis module and the energy beam are directed at different locations on the test sample. The test sample (and/or the analysis module) is then repositioned after the cleaning operation to align the probe beam (or probe structure) with the analysis area of the thin film layer. This allows the focusing optics or probe structure of the analysis module to be kept out of the vicinity of the portion of the contaminant layer being vaporized, thereby minimizing the risk of any contaminant redeposition on the measurement focusing optics or probe structure.

The present invention will be more fully understood in view of the following description and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1 a and 1 b show conventional wafer cleaning systems.

FIGS. 2 a and 2 b show a thin film analysis system in accordance with an embodiment of the present invention.

FIGS. 3 a and 3 b show a thin film analysis system in accordance with another embodiment of the present invention.

DETAILED DESCRIPTION

FIG. 2 a shows a thin film analysis system 200 in accordance with an embodiment of the present invention. Analysis system 200 comprises a stage 220, an energy beam source 230, and an analysis module 240. Stage 220 holds a test sample 210 that comprises a thin film layer 212 formed on a substrate 211. Substrate 211 can comprise any structure on which thin film layer 212 can be formed, including a single-layer structure (such as a silicon wafer) or a multi-layer structure (such as an additional thin film layer or layers formed on a silicon wafer). Test sample 210 also includes a contaminant layer 213 formed on the surface of thin film layer 212. Contaminant layer 213 can comprise any unwanted material on the surface of thin film layer 212.

An analysis operation performed using analysis system 200 actually comprises two steps—a cleaning operation and a measurement operation. During the cleaning operation, a small portion of contaminant layer 213 is removed. The exposed portion (i.e., analysis area) of thin film layer 212 is then analyzed during the measurement operation. According to an embodiment of the present invention, the position of stage 220 can be shifted relative to energy beam source 230 and analysis module 240 to enable thin film analysis at multiple locations on test sample 210. According to an embodiment of the present invention, stage 220 can include a positioning mechanism 221 to enable this positional shifting.

To perform a cleaning operation, energy beam source 230 directs an energy beam 231 at a spot 214 a on contaminant layer 213. Energy beam 231 is configured to remove a portion of contaminant layer 213 by heating contaminant layer 213 directly or by heating the underlying portion of thin film layer 212 or substrate 211. The portion of contaminant layer 213 heated in this manner is eventually vaporized, thereby exposing the underlying portion of thin film layer 212. As noted previously, this removal process can be aided by other mechanisms besides heating, including the direct stimulation of the bonds between contaminant layer 213 and thin film layer 212 by photons from energy beam 231.

Because the heating from energy beam source 230 is confined to a localized area, the cleaning operation can be performed very rapidly, which minimizes any impact on analysis throughput. The potential for damage to the underlying thin film layer 212 and/or substrate 211 is minimal because only a small portion of test sample 210 is heated. This risk of damage can be further reduced by performing the cleaning operation on non-functional regions of test sample 210 (e.g., regions such as scribe lines that will not be part of the functional portion(s) of the final devices to be made from test sample 210).

The amount of contaminant layer 213 to be removed depends on the measurement requirements of analysis module 240. Modern thin film analysis tools generally require an analysis area of at least 20 μcm×20 μcm. Therefore, at least a 20 μcm×20 μcm portion of contaminant layer 213 would need to be removed for such systems. However, to ensure that the entire analysis area is uniformly cleaned, a larger portion of contaminant layer 213 could be removed.

According to an embodiment of the present invention, energy beam source 230 could comprise a pulsed laser. For example, contaminant layer 213 could comprise a 5 angstrom thick layer of water and organic materials (which is similar to contamination layers often formed on modern thin film layers during production). A number of pulses or even a single pulse from a 5–100 μJoule laser having a 1–1000 ns pulse duration could then heat the desired portion of contaminant layer 213 to between roughly 300° C. to 1000° C., which is a temperature range sufficient to vaporize that portion of contaminant layer 213. According to another embodiment of the present invention, energy beam source 230 could comprise a Q-switched laser delivering a relatively high peak power, such as a frequency-doubled or tripled YAG (yttrium aluminum garnet) laser operating at wavelengths of 532 nm or 355 nm, respectively. According to another embodiment of the present invention, other types of pulsed lasers operating at different wavelengths might be used including pulsed diode or alexandrite lasers. According to another embodiment of the present invention, a continuous laser, such as an argon-ion laser, could be externally modulated (such as with an acousto-optic or electro-optic modulator) to produce a pulse. According to another embodiment of the present invention, energy beam source 230 could include focusing optics such as an optical fiber 232 (shown using dotted lines) and a lens system to deliver a beam of the desired size and energy to spot 214 a from a remote location, i.e., the optional optical fiber 232 could transmit energy beam 231 from a remote beam generator to spot 214 a. According to another embodiment of the present invention, energy beam source 230 could comprise a flashlamp coupled to focusing optics to direct the high intensity light to the desired area on contaminant layer 213.

Once the cleaning operation is completed, the measurement operation can be performed. Because test sample 210 does not need to be transferred to a different tool or process chamber, the measurement operation can be performed immediately following the cleaning operation, so that the chances of recontamination of the exposed portion (analysis area) of thin film layer 212 are minimized. For explanatory purposes, FIG. 2 b depicts analysis module 240 as including a xenon lamp 241, a rotating polarizer 242, a focusing mirror 243, a fixed polarizer 244, a spectrometer 245, and a CCD detector 246 for performing a spectroscopic ellipsometry analysis. However, analysis module 240 can comprise a system or systems for any type of analysis that would benefit from removal of contaminant layer 213, including SWE, SE, reflectometry (optical or x-ray), GXR, XRF, EMP, and non-contact or contact-based electrical analysis, among others. Note that analysis system 200 can comprise a conventional thin film analysis system to which energy beam source 230 is added, thereby minimizing the footprint of analysis system 200.

As indicated in FIG. 2 b, contaminant layer 213 includes an opening 214 b formed by the laser heating of spot 214 a during the preceding cleaning operation (as shown in FIG. 2 a). The measurement operation therefore can be performed directly on thin film layer 212 through opening 214 b. Xenon lamp 241 directs a diverging light beam 247 through rotating polarizer 242 at focusing mirror 243, which reflects and focuses beam 247 through opening 214 b in contaminant layer 213 onto an analysis area 215 on thin film layer 212. Light beam 247 is reflected by thin film layer 212 as a diverging beam, which passes through fixed polarizer 244 and spectrometer 245 before being measured by CCD detector 246 to determine the thickness of thin film layer 212.

In this manner, a localized cleaning operation can be efficiently combined with a measurement operation to ensure accurate and repeatable thin film analyses. Because both energy beam 231 and the probe beam from analysis module 240 (here represented by light beam 247) are simultaneously directed at substantially the same location on test sample 210, the position of test sample 210 does not have to be adjusted between cleaning and measurement operations. Therefore, the measurement operation can be performed immediately after the cleaning operation to ensure that a new contaminant layer is not reformed over analysis area 215.

FIG. 3 a shows a thin film analysis system 300 in accordance with an embodiment of the present invention. Analysis system 300 comprises a stage 320, an energy beam source 330, and an analysis module 340. Stage 320 includes a positioning mechanism 321 and a platform 322. Positioning mechanism 321 allows the position of platform 322 to be shifted relative to energy beam source 330 and analysis module 340. Platform 322 holds a test sample 310 that comprises a thin film layer 312 formed on a substrate 311. Substrate 311 can comprise any material on which thin film layer 312 can be formed, including a single material (such as a silicon wafer) or a plurality of materials (such as an additional thin film layer or layers formed on a silicon wafer). Test sample 310 also includes a contaminant layer 313 formed on the surface of thin film layer 312. Contaminant layer 313 can comprise any unwanted material on the surface of thin film layer 312.

Unlike in analysis system 200 shown in FIGS. 2 a and 2 b, energy beam source 330 and analysis module 340 are not simultaneously focused at the same location on test sample 310. Consequently, an analysis operation performed using analysis system 300 actually comprises three steps—a cleaning operation, a positioning operation, and a measurement operation. During the cleaning operation, a small portion of contaminant layer 313 is removed by the energy beam from energy beam source 330. Then during the positioning operation, test sample 310 is positioned such that the probe beam of analysis module 340 is aligned with the portion of thin film layer 312 exposed during the cleaning operation. The exposed portion of thin film layer 312 can then be analyzed by analysis module 340 during the measurement operation.

To perform a cleaning operation, energy beam source 330 directs an energy beam 331 at a point 314 a on contaminant layer 313. Energy beam 331 is configured to remove a portion of contaminant layer 313 by heating contaminant layer 313 directly or by heating the underlying portion of thin film layer 312 or substrate 311. The portion of contaminant layer 313 heated in this manner is vaporized, thereby exposing the underlying portion of thin film layer 312.

Because the heating from energy beam source 330 is confined to a localized area, the cleaning operation can be performed very rapidly, which minimizes any impact on analysis throughput. The potential for damage to the underlying thin film layer 312 and/or substrate 311 is minimal because only a small portion of test sample 310 is heated. This risk of damage can be further reduced by performing the cleaning operation on non-functional regions of test sample 310.

The amount of contaminant layer 313 to be removed depends on the measurement requirements of analysis module 340. As described previously, modern thin film analysis tools generally take measurements within a roughly 20 μcm×20 μcm spot. Accordingly, energy beam source 330 could comprise a 5–100 μJoule pulsed laser with a pulse duration of 1–100 ns, which would be capable of vaporizing a 20 μcm×20 μm (or slightly larger) portion of a 5 angstrom thick contaminant layer (contaminant layer 313) of adsorbed water vapor. According to an embodiment of the present invention, energy beam source 330 could comprise a Q-switched laser delivering a relatively high peak power, such as a frequency-doubled or tripled YAG (yttrium aluminum garnet) laser operating at wavelengths of 532 nm or 355 nm, respectively. According to another embodiment of the present invention, energy beam source 330 could include focusing optics such as an optical fiber and a lens system to deliver a beam of the desired size and energy to spot 314 a from a remote location, i.e., the optical fiber could transmit energy beam 331 from a remote beam generator to spot 314 a. According to another embodiment of the present invention, energy beam source 330 could comprise a flashlamp coupled to focusing optics to direct the high intensity light to the desired area on contaminant layer 213.

As indicated in FIG. 3 b, the cleaning operation creates an opening 314 b in contaminant layer 313 (at spot 314 a shown in FIG. 3 a), thereby exposing an analysis area 315 of thin film layer 312. A positioning operation then aligns analysis area 315 with the probe beam from analysis module 340, in this case an electron beam (e-beam) 346. This positioning operation is performed by positioning mechanism 321, which shifts platform 322 relative to analysis module 340 (as indicated by the phantom lines). While a lateral shift is indicated in FIG. 3 b, any other type of positioning motion could be used, including a rotational or vertical shift. In this manner, the probe beam focusing optics in analysis module 340 can be maintained at a distance from the portion of contaminant layer 313 being removed during the cleaning operation (point 314 a shown in FIG. 3 a). This in turn minimizes the risk of any of vaporized contaminant layer 313 redepositing on the probe beam focusing optics or probe structure of analysis module 340.

After the positioning operation is completed, the measurement operation can be performed by analysis module 340. Because test sample 310 does not have to be transferred to a different tool or process chamber, there is little chance of recontamination of analysis area 315. For explanatory purposes, FIG. 3 b depicts analysis module 340 as including a corona discharge gun 344, a charge mask 345, and a vibrating probe 346 for performing a non-contact electrical analysis, as described in co-owned U.S. Pat. No. 5,485,091. However, analysis module 340 can comprise a system or systems for any type of analysis that would benefit from removal of contaminant layer 313, including SWE, SE, reflectometry, GXR, XRF, EMP, and non-contact or contact-based electrical analysis, among others. Note that analysis system 300 can comprise a conventional thin film analysis system to which energy beam source 330 is added, thereby minimizing the footprint of analysis system 300.

As indicated in FIG. 3 b, the measurement operation is performed through opening 314 b formed in contaminant layer 313 during the preceding cleaning operation. Corona discharge gun 344 produces a corona discharge 347 that is shaped into a negative charge beam 348 by charge mask 345. Negative charge beam 348 deposits a negative charge onto analysis area 315 through opening 314 b in contaminant layer 313. The resulting change in surface potential can then be measured by vibrating probe 346 to determine the thickness and electrical properties of thin film layer 312.

In this manner, a localized cleaning operation can be efficiently combined with a measurement operation to ensure accurate and repeatable thin film analyses. By allowing the position of test sample 310 to be shifted between the cleaning and measurement operations, energy beam 331 and the probe beam of analysis module 340 (here represented by negative charge beam 348) do not need to be focused at the same location on test sample 310. Therefore, the focusing optics of analysis module 340 can be distanced from any contamination released during the cleaning operation.

Although the present invention has been described in connection with several embodiments, it is understood that this invention is not limited to the embodiments disclosed, but is capable of various modifications that would be apparent to one of ordinary skill in the art. Thus, the invention is limited only by the following claims. 

1. A thin film analysis system for analyzing a test sample, the test sample comprising a thin film formed on a substrate and a contaminant layer formed on the thin film, the thin film analysis system comprising: an energy beam source for directing an energy beam at the contaminant layer during a cleaning operation, the energy beam being configured to provide localized heating to a portion of the contaminant layer, thereby removing the portion of the contaminant layer and exposing an analysis area on the thin film; a thin film analysis module for measuring the thin film at the analysis area, wherein the thin film analysis module is configured to apply one of a probe beam and a probe structure to the analysis area during a measurement operation; and a positioning mechanism for aligning the energy beam with the portion of the contaminant layer during the cleaning operation and for aligning one of the probe beam and the probe structure with the analysis area during the measurement operation.
 2. A method for analyzing a test sample, wherein a contaminant layer covers a thin film of the test sample, the method comprising: placing the test sample on a stage; directing an energy beam at a first location on the contaminant layer while the test sample is on the stage, the energy beam locally heating a first portion of the contaminant layer to create an opening in the contaminant layer; and measuring the thin film by directing a probe beam through the opening at a first analysis area on the thin film, wherein measuring the test sample comprises adjusting the stage to align the first analysis area with the probe beam.
 3. The method of claim 2, wherein adjusting the stage comprises performing a lateral shift of the stage.
 4. The method of claim 2, wherein adjusting the stage comprises performing a rotational shift of the stage.
 5. A thin film analysis system for analyzing a test sample, the test sample comprising a thin film formed on a substrate and a contaminant layer formed on the thin film, the thin film analysis system comprising: means for directing an energy beam at the contaminant layer during a cleaning operation, the energy beam locally heating a portion of the contaminant layer to form an opening in the contaminant layer that exposes an analysis area on the thin film; and means for performing a measurement operation through the opening at the analysis area, wherein the means for performing the measurement operation comprises: means for applying one of a probe beam and a probe structure to the thin film during the measurement operation, and means for adjusting a position of the test sample to align the one of the probe beam and the probe structure with the analysis area.
 6. The thin film analysis system of claim 5, further comprising means for adjusting the position of the test sample to align the energy beam with the portion of the contaminant layer. 